Transmitter power monitor

ABSTRACT

The invention provides an in-line power monitor for an RF transmission line that is capable of being calibrated in-line during live conditions at the exact power level and frequency where it is used. This device uses forward and reflected directional couplers and a non-directional coupler to sample the RF voltage on the transmission line. The RF voltage of the forward and reflected channels are each split into two paths, one going to a test port and the other leading to additional circuitry which prepares the signals of the forward and reflected channels for output to power displays. Additionally, the monitor allows the user to compensate for any voltage offsets introduced by various circuitry components. Further, the monitor also allows to user to individually calibrate the output of the forward and reflected channels by applying an adjustable gain ratio correction to each channel.

CROSS REFERENCE TO RELATED APPLICATION

This application claims the priority benefit of U.S. Provisional PatentApplication Ser. No. 61/123,830 filed Apr. 11, 2008.

FIELD OF THE INVENTION

This invention relates to an electrical instrument for monitoring RFtransmitters and transmission lines to measure and report values forboth the forward and reflected transmission line power.

BACKGROUND OF THE INVENTION

The output power and resultant geographic coverage of radio andtelevision broadcast transmission systems are regulated in the UnitedStates by the Federal Communications Commission (“FCC”). Title 47, Part73.644 of the FCC rules and regulations regarding broadcast transmissionstates in part: “If electrical devices are used to determine the outputpower, such devices must permit determination of this power within anaccuracy of ±5% of the power indicated by the full scale reading of theelectrical indicating instrument of the device.”

While in-line power measurement instruments are designed andmanufactured such that they are capable of measuring transmission powerto within ±5% at the time of shipment, all test instruments requireperiodic calibration in order to maintain their design performancelevels and remain in compliance with FCC rules and regulations.

Calibration approaches for currently available power measurementinstruments used in broadcast applications call for the removal of thepower monitor from the transmission line so that it may be returned tothe factory for calibration. The major issue associated with thisprocess is that the transmitter must be shut down while the in-linepower monitor is removed from the system and temporarily replaced witheither a spare power monitor or a temporary transmission line section.Due to the inherent inconvenience associated with a transmitter shutdown and equipment removal, most power monitors are either calibratedvery infrequently or not calibrated altogether.

Another issue associated with the current factory calibration proceduresis that most factories are not capable of calibrating power monitors atthe exact power levels and frequencies they are used at in the field.Because the detectors in power monitors do not provide a uniformflatline response at every frequency and power level, factory calibratedpower monitors are inherently inaccurate if not used at the factorycalibrated power level and frequency. These inaccuracies coupled with adrift in the calibration over time can render monitors incapable ofmeasuring transmission line power to within ±5%, taking them out ofcompliance with FCC rules and regulations.

In view of these limitations, a need exists for a power monitor that iscapable of being calibrated in-line during live conditions at the exactpower level and frequency where it is used.

The instrument of the present invention satisfies the needs describedabove and affords other features and advantages heretofore notobtainable.

SUMMARY OF THE INVENTION

This invention provides an electrical instrument for monitoring theforward and reflected RF power along a transmission line and is capableof being calibrated in-line during live conditions at the exact powerand frequency where it is used.

In some embodiments, forward and reflected directional couplers are usedto sample the forward and reflected voltage on the transmission line.The RF signals from the couplers are routed to a pair of powersplitters, with one for each of the forward and reflected channels. Eachpower splitter provides a pair of outputs, one of which is sent to atest port, the other sent to a square-law diode detector circuit. Thedetector circuits convert the sampled forward and reflected transmissionline RF voltages into small DC voltages.

The respective small DC voltages are each amplified by a precision gainstage, converted to digital signals by an analog to digital converterand sent to the system microcontroller. The microcontroller appliestemperature correction and calibration scaling to the signals andproduces digital outputs. The digital outputs are converted to analogsignals by a digital to analog converter and directed to a precisionbuffer amplifier stage. Thereafter the signals are then made availableto the user for remote monitoring via a male DE9 9-pin D-sub socket. Theremote monitoring can be performed using forward and reflected powerdisplays.

In some embodiments, the forward power measurement is in-line calibratedby connecting a reference power meter to the forward test port tomeasure the transmission line forward power, the attenuation databetween the transmission line and the forward test port is inputted intothe reference power meter, the reference power meter reading is comparedto the forward power display, and the forward calibration adjustment isappropriately manipulated until the forward power display reading issubstantially equivalent to the reference power meter reading.

In some embodiments, the reflected power measurement is in-linecalibrated by connecting a reference power meter to the reflected testport to measure the transmission line reflected power, the attenuationdata between the transmission line and the reflected test port isinputted into the reference power meter, the reference power meterreading is compared to the reflected power display, and the reflectedcalibration adjustment is appropriately manipulated until the reflectedpower display reading is substantially equivalent to the reference powermeter reading.

Additionally, some embodiments are capable of calculating andcompensating for any offsets introduced by the circuitry in the forwardand reflected signal paths leading up to and including themicrocontroller. The circuitry is “zeroed” by pressing and holding thecalibration button with zero power in the transmission line, duringwhich time the LED will blink. When the calibration button is released,the offsets are calculated for the individual forward and reflectedchannels and the offset compensation is applied to each channel.

Some embodiments also include a third non-directional coupler thatprovides a sample of the main line transmission voltage, but is notconfigured to provide directionality.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded view of an embodiment of the invention;

FIG. 2 is a top plan view of the device of FIG. 1;

FIG. 3 is a block diagram illustrating the arrangement of the electricalcomponents used in the device of FIGS. 1 and 2;

FIG. 4 is an interconnection diagram of some components depicted inFIGS. 1, 2 and 3;

FIG. 5A-H is a flowchart of the firmware contained in themicrocontroller of FIGS. 1, 2, 3 and 4; and

FIG. 6A-H are electrical schematics of the device in FIGS. 1, 2, 3, 4,and 5.

DETAILED DESCRIPTION OF THE INVENTION

Referring more particularly to the drawings, there is shown anembodiment of the invention, a transmitter power monitor capable ofbeing calibrated while operating under live conditions.

Referring to FIG. 1, a transmitter power monitor 100 comprises atransmission line section 165 having a transmitter end 166 and a loadend 167. A rectangular body 170 is fastened to the top of thetransmission line section 165. The body 170 has a cover 175. Forward andreflected directional couplers 101 and 102 and non-directional coupler103 are located inside the body 170. In the preferred embodiment,non-directional coupler 103 is mounted on a RF board 185, while the RFboard 185 is placed on top of forward and reflected couplers 101 and102. All of the couplers 101, 102, and 103 interface with the RF board.

A logic board 186 is placed on top of and interfaces with the RF board185. The logic board has a male DE9 9-pin D-sub socket 157, an LED 137,and forward and reflected calibration adjustments 130 and 131. Thesocket 157 is accessible through the cover 175 and LED 137 is visiblethrough the cover 175. The cover 175 must be removed to gain access tothe forward and reflected calibration adjustments 130 and 131. Also,placed on top of and interfacing with the radio frequency board 185 arethe forward test port 110, reflected test port 111, and non-directionaltest port 112. The test ports 110, 111, and 112 are female type “N”connectors. The forward and reflected test ports 110 and 111 areterminated with 2 Watt loads 180 and 181. The test ports 110, 111, and112 are fastened to the body 170. A sticker 187 containing thecalibration data for test ports 110, 111, and 112 is located on the body170.

Referring to the embodiment shown in FIG. 2, a transmitter power monitor200 comprises a transmission line section 265 with a transmitter end 266and an antenna end 267. A body 270 is fastened to the top of thetransmission line 265. The body 270 has a cover 275. A male DE9 9-pinD-sub socket 257 is accessible through the cover 275 and an LED 237 isvisible through the cover 275. A forward test port 210, reflected testport 211, and non-directional test port 212 are fastened to the body270.

Referring to the embodiment shown in FIG. 3, radio frequency (RF)voltage samples of the transmission line power are made available by theforward and reflected directional couplers, 301 and 302. In thepreferred embodiment, the couplers 301 and 302 are both part number7006A216 from Bird Technologies Group. The samples of the maintransmission line power provided by the couplers 301 and 302 areapproximately −55 dB from the main transmission line power. Thetransmission line 365 has a transmitter end 366 and an antenna end 367.The forward coupler is located at the transmitter end 366 and thereflected coupler is located at the antenna end 367.

The RF voltage samples from the forward directional coupler 301 arerouted to the forward power splitter 305, while RF voltage samples fromthe reflected directional coupler 302 are routed to the reflected powersplitter 306. The power splitters 305 and 306 also contain someresistive attenuation for the dual purpose of setting the appropriatevoltage levels for the detector circuits 315 and 316, as well asproviding isolation between circuit components. In the preferredembodiment, the power splitters 305 and 306 are contained in an RFcircuit assembly which is part number 7006A114 from Bird TechnologiesGroup; while the detectors 315 and 316 are each part number SMS7630-005from Skylink. However, a person having ordinary skill in the art canchoose to use other power splitters and detectors as he sees fit.

The forward power splitter 305 outputs a RF voltage to both the forwardtest port 310 and the forward detector 315. The reflected power splitter306 outputs a RF voltage to both the reflected test port 311 and thereflected detector 316. The detectors 315 and 316 are square-law diodedetectors. A non-directional coupler 303 provides a sample of the mainline transmission voltage to a non-directional test port 312. Thenon-directional coupler 303 is contained in a RF circuit assembly whichis part number 7006A114 from Bird Technologies Group. However, a personhaving ordinary skill in the art can choose to use other non-directionalcouplers as he sees fit.

During factory calibration, the attenuation relationship in terms ofmagnitude and frequency response between the main transmission line 365and each test port 310, 311, and 312, are determined as a function offrequency. This data becomes the test port calibration data. Thenon-directional test port 312, which is not configured to providedirectionality, is typically used for main transmission line 365 energywaveform analyses with spectrum analyzers or modulation analysis tools.In the preferred embodiment, the test ports 310, 311, and 312 are femaletype “N” connectors, but a person having ordinary skill in the art canchoose to use other types of ports as he sees fit.

The forward and reflected detectors 315 and 316 use diodes to convertthe RF voltages into small direct current (DC) voltages. The inputs toeach of the detectors 315 and 316 are set at a level of approximately−20 dBm maximum, such that the detectors are always operating within thesquare law region of their dynamic response. The detectors 315 and 316each provide a DC voltage output of approximately 1 mV.

The output of the forward detector 315 is amplified by a forward gainstage 320 and the output of the reflected detector 316 is amplified by areflected gain stage 321. The gain stages 320 and 321 are precisionoperational amplifiers, but a person having ordinary skill in the artcan choose to use any operational amplifiers that he sees fit.

In the preferred embodiment, the output of the gain stages 320 and 321is approximately 2 volts DC at the full scale rating of the instrument.The gain stages 320 and 321 are part number AD8628 from Analog Devices,but a person having ordinary skill in the art can choose to use otheroperational amplifiers as he sees fit.

Gain stages 320 and 321 output the amplified DC voltage to an analog todigital converter 325. The forward calibration adjustment 330, reflectedcalibration adjustment 331, and temperature sensor 340 also send signalsto the analog to digital converter 325.

In the preferred embodiment the forward calibration adjustment 330 andreflected calibration adjustment 331 preferably produce DC voltages at alevel comparable to the output of gain stages 320 and 321, but a personhaving ordinary skill in the art can choose to use any voltage sourceand range that he sees fit. The forward calibration adjustment 330 andreflected calibration adjustment 331 each consist of a 5k potentiometerin a voltage divider circuit with a 4.9 k resistor. The analog todigital converter 325 preferably has a resolution of 12 bits, but aperson having ordinary skill in the art can use any analog to digitalconverter having any resolution that he sees fit.

The analog to digital converter 325 digitizes the signals from theforward gain stage output 320, reflected gain stage output 321, forwardcalibration adjustment 330, reflected calibration adjustment 331, andtemperature sensor 340 and sends the digital signals to themicrocontroller 335. The temperature sensor 340 is located in closeproximity to the detectors 315 and 316. The output of detectors 315 and316 varies with the ambient air temperature. The microcontroller 335uses the digitized temperature sensor 340 output in conjunction with thetemperature characterization curve of the detectors 315 and 316 storedin microcontroller 335 to compensate for the effects of thermallyinduced drift in the forward and reflected detectors 315 and 316. In thepreferred embodiment, the temperature sensor is a TMP36 from AnalogDevices.

The microcontroller 335 also receives the output of the calibrationbutton 336. The power monitor 300 is capable of calculating andcompensating for any offsets introduced by circuitry in the forward andreflected channel signal paths located between the transmission line 365and up to and including microcontroller 335. This helps to ensure thatthe forward and reflected channels of power monitor 300 will output apower level substantially equal to zero, when zero power is travellingthrough the transmission line 365. In the preferred embodiment, thisprocess compensates for offsets introduced by the forward and reflecteddirectional couplers 301 and 302, forward and reflected power splitters305 and 306, forward and reflected detectors 315 and 316, forward andreflected gain stages 320 and 321, analog to digital converter 325,microcontroller 335, and any other circuitry between transmission line365 and microcontroller 335.

In the preferred embodiment, the circuitry is zero power calibrated or“zeroed” by pressing and holding the calibration button 336 for aspecific amount of time with zero power in the transmission line 365,during which time the LED 337 will blink. After the calibration button336 is released, the forward and reflected channel zero power offsetsare calculated and the zero power offset compensation is applied.Normally, this process would be done either during a factory calibrationor in the field when a customer is performing calibration while thepower monitor 300 is installed.

The microcontroller 335 provides an output to the LED 337, whichprovides a visual indication of the zero power offset calibrationstatus. In the preferred embodiment, the LED 337 states are as follows:the LED 337 turns off in when the power monitor 300 is being “zeroed”;LED 337 turns and remains on when the power monitor 300 is “zeroed”; andLED 337 blinks if the power monitor 300 is not “zeroed” and is not being“zeroed”.

The main task of the microcontroller 335 is to provide some digitalaveraging of the data received from the analog to digital converter 325,provide a means to perform temperature correction, provide a means toperform zero offset power correction, and apply the forward andreflected channel gain ratio correction dictated by the forward andreflected calibration adjustments 330 and 331. The microcontrollercorrelates the voltage output of the forward and reflected calibrationadjustments 330 and 331 to an overall circuit gain ratio correctionsetting established in the microcontroller firmware and applies theappropriate gain ratio correction to each respective channel.

The microcontroller 335 applies the temperature correction, zero poweroffset correction, and circuit gain ratio correction to the digitalforward and reflected channel signals, and outputs the corrected digitalforward and reflected channel signals to a digital to analog converter345, which converts the corrected digital signals to analog DC voltages.The output of the digital to analog converter 345 is adjustable, therebyallowing the entire system to be calibrated using a high powerreference. The digital to analog converter 345 sends the respectiveforward and reflected corrected DC voltages to a forward buffer 350 andreflected buffer 351. The buffers 350 and 351 are precision gain stages,which ensure that a low source impedance is possible with theinstrument, thereby minimizing the potential for electrical noise. Thegain stages used in the preferred embodiment are precision operationamplifiers, but a person having ordinary skill in the art can use anyprecision gain stage that he sees fit.

The corrected DC voltage output of the forward buffer 350 is then sentto the forward power calibrated output 355 and the corrected DC voltageoutput of the reflected buffer 351 is sent to the reflected powercalibrated output 356. In the preferred embodiment, the calibratedoutputs 355 and 356 are pins in a male DE9 9-pin D-sub socket on thebody of the transmitter power monitor, but a person having ordinaryskill in the art can use any output method that he sees fit. In thepreferred embodiment, the transmitter power monitor provides 0-4 VDC atthe calibrated outputs 355 and 356. These voltages are linearlyproportional to the main transmission line power in that if a particulartransmitter power monitor has a 10 kW full scale power range at 4.0V, anoutput of 2.0V would correspond to 5 kW. Although the calibrated outputs355 and 356 have a linear 0-4V DC output, it is contemplated that aperson having ordinary skill in the art can use any output scale andrange that he sees fit.

A user can then monitor the forward and reflective power levels byconnecting a forward power display 360 to the forward power calibratedoutput 355 and a reflected power display 361 to the reflected powercalibrated output 356. The forward and reflected power displays 360 and361 are capable of displaying the full scale power equivalent of thecorrected DC voltage. Possible types of power displays 360 and 361include analog meters or a computer system, but a person having ordinaryskill in the art can use any display method that he sees fit.

Further, in addition to “zeroing” the power monitor, a user cancalibrate the individual forward and reflected power measurements byapplying a gain ratio correction to the channels, under actual operatingconditions, and at the exact power level and frequency where the powermonitor 300 is used, thereby minimizing errors associated with thedirectional coupler frequency response and detector linearity.

In one embodiment, the power monitor forward measurement is in-linecalibrated by connecting a reference power meter to the forward testport 310 to measure the forward power on transmission line 365, theattenuation data between the transmission line 365 and the forward testport 310 is inputted into the reference power meter, and the forwardcalibration adjustment 330 is appropriately manipulated until the outputof the forward power channel correctly corresponds to the forward poweron transmission line 365. In the preferred embodiment, the output of theforward power channel is ascertained through the use of a forward powerdisplay 360 connected to the forward power calibrated output 355.

Stated alternatively, to calibrate the forward power measurement, anaccurate reference power meter is connected to the forward test port310, the forward test port 310 attenuation data is then entered into thereference power meter to establish the correct attenuation relationshipbetween forward test port 310 and transmission line 365. Upon enteringthe attenuation data, the reference power meter reading is equivalent tothe forward power on the transmission line 365. The calibration processis completed by adjusting the transmitter power monitor forwardcalibration adjustment 330 accordingly so that the forward power display360 reading is substantially equivalent to the reference power meterreading. The forward power display 360 reading is substantiallyequivalent to the reference power meter reading when the forward powerdisplay 360 reading is within ±1% of the reference power meter reading.Preferably, the forward calibration adjustment 330 is adjusted until theforward power display 360 reading is equal to the reference power meterreading.

In one embodiment, the power monitor reflected measurement is in-linecalibrated by connecting a reference power meter to the reflected testport 311 to measure the reflected power on transmission line 365, theattenuation data between the transmission line 365 and the reflectedtest port 311 is inputted into the reference power meter, and thereflected calibration adjustment 331 is appropriately manipulated untilthe output of the reflected power channel correctly corresponds to thereflected power on transmission line 365. In the preferred embodiment,the output of the reflected power channel is ascertained through the useof a reflected power display 361 connected to the reflected powercalibrated output 356.

Stated alternatively, to calibrate the reflected power measurement, anaccurate reference power meter is connected to the reflected test port311, the reflected test port 311 attenuation data is then entered intothe reference power meter to establish the correct attenuationrelationship between reflected test port 311 and transmission line 365.Upon entering the attenuation data, the reference power meter reading isequivalent to the reflected power on the transmission line 365. Thecalibration process is completed by adjusting the transmitter powermonitor reflected calibration adjustment 331 accordingly so that thereflected power display 361 reading is substantially equivalent to thereference power meter reading. The reflected power display 361 readingis substantially equivalent to the reference power meter reading whenthe reflected power display 361 reading is within ±1% of the referencepower meter reading. Preferably, the reflected calibration adjustment331 is adjusted until the reflected power display 361 reading is equalto the reference power meter reading.

Further, in other embodiments, it is contemplated that a user cancalibrate the output of the forward and reflected channels by correctingthe gain ratio of the forward and reflected channels throughmanipulating the gains and attenuation of the individual circuitcomponents comprising the forward and reflected channel signal paths.The circuitry components include gain stages 320 and 321 and buffers 350and 351. When manipulating the gains and attenuation, one should bemindful to keep the operation of detectors 315 and 316 within thesquare-law region. In the preferred embodiment, the forward andreflected channel gain ratio is 10:1.

Further, in other embodiments, it is contemplated that a user canreplace microcontroller 335 with a suitable microprocessor, applicationspecific integrated circuit, field programmable gate array, or discretecircuitry. It is also contemplated that the functions of the forward andreflected gain stages 320 and 321, analog to digital converter 325,digital to analog converter 345, and forward and reflected buffers 350and 351 could be performed on-board microcontroller 335.

Referring to the embodiment shown in FIG. 4, an interconnection diagramis shown which conveys the pin connections of the analog to digitalconverter 425, microcontroller 435, digital to analog converter 445,reflected buffer 451, and forward buffer 450. For simplicity, the powerconnections, ground connections, capacitors, resistors, and othercomponents are not shown.

The analog to digital converter 425 receives an input from the reflectedcalibration adjustment 431 on pin 1, the forward calibration adjustment430 on pin 2, the reflected gain stage 421 on pin 3, the forward gainstage 420 on pin 5, the temperature sensor 440 on pin 6, and the clock426 on pin 19. In the preferred embodiment, the analog to digitalconverter is Texas Instrument part number ADS 7844, but a person havingordinary skill in the art can use any analog to digital converter thathe sees fit.

The microcontroller 435 receives an input from the calibration button436 on pin 33, outputs a clock pulse on pin 3 and outputs a signal tothe LED 437 from pin 35. As can be seen in FIG. 4, pins 18, 16, 17, 15,and 19 of the analog to digital converter 425 interface with pins 41,43, 1, 2, and 3 of the microcontroller 435. In the preferred embodiment,the microcontroller is an ATMEGA16L8AU from Amtel.

Turning to the digital to analog converter 445, as can be seen from FIG.4, pins 1, 3, 19, and 20 of the microcontroller 435 interface with pins9, 16, 11, and 15 of the digital to analog converter 445. In thepreferred embodiment, the digital to analog converter 445 is AnalogDevices part number AD5555, but a person having ordinary skill in theart can use any digital to analog converter that he sees fit.

Turning to the reflected and forward buffers 451 and 450, pins 6 and 2of the reflected buffer 451 interface with pins 1 and 3 of the digitalto analog converter 445. Meanwhile, pins 2 and 6 of the forward buffer450 interface with pins 6 and 8 of the digital to analog converter 445.In the preferred embodiment, both the reflected buffer 451 and forwardbuffer 450 are Analog Devices part number AD8628, which were selectedfor their low offset voltage and drift, but a person having ordinaryskill in the art can use any operational amplifier that he sees fit.

The digital to analog converter 445 and buffers 451 and 450 areconfigured for positive voltage output. The reflected calibrated poweroutput 456 is taken from pin 6 of the reflected buffer 451; while theforward calibrated power output 455 is taken from pin 6 of the forwardbuffer 450. In the preferred embodiment, buffers 451 and 450 areconfigured for unity gain, but a person having ordinary skill in the artcan use any configuration that he sees fit.

Referring to FIG. 5 A-H, some components are referred to with referenceto FIG. 3. FIG. 5 A-H is a flowchart of the firmware contained in themicrocontroller 335. In stages 500 and 502, the microcontroller 335 ispowered up, the variables are initialized, the calMode, newCalBuffer,and newInputData flags are cleared, the calButtonTimer is started at 0,the adTimer is started at UPDATECOUNT, and the forward and reflectedzero power offset counts are retrieved from the memory. In the preferredembodiment, UPDATECOUNT=3.

In stage 504, the program verifies that the forward and reflected zeropower offset counts are within the limits specified in the program. Ifone of the zero power offset counts is not within the specified limit,the default zero power offset count is loaded for the zero power offsetcount and the calDone flag is cleared. The program progresses to stage506 after both of the zero power offset counts are verified. If the zeropower offset counts are within the specified limits, the calDone flag isset and the program progresses to stage 506. In the preferredembodiment, a forward or reflected power offset count is not within thespecified limit if both of the following do not occur, the zero poweroffset count is less than or equal to MAXZEROOUT and is greater than 0.Further, the default zero power offset count is 0 in the preferredembodiment.

In stage 506 the program considers the status of the calMode flag. Ifthe calMode flag is set, the program will turn off the LED 337 andprogress to stage 510. If the calMode flag is not set, the programprogresses to stage 508. In stage 508, the program blinks LED 337 if thecalDone flag is not set, but turns on LED 337 if the calDone flag isset. Following stage 508, in stage 510, the program considers theadTimer status. If the adTimer is less than or equal to UPDATECOUNT, theprogram progresses to stage 520. However, the program progresses tostage 512 if the adTimer is greater than UPDATECOUNT.

Stages 512 through 518 use the information received from the analog todigital converter 325 to create input data. The input data consists of aseries of arrays, one for each type of data sent from the analog todigital converter 325. The analog to digital converter 325 sendsconverted data to the microcontroller 335 from the forward calibrationadjustment 330, forward gain stage 320, temperature sensor 340,reflected gain stage 321, and reflected calibration adjustment 331. Thenumber of elements in each array is equal to the filter value. In thepreferred embodiment, the filter value is 16, but a person havingordinary skill in the art can use any number of elements that he seesfit.

In stage 512, if the analog to digital channel is greater than 7, thechannel n is set to 0 and the information received from the analog todigital converter is stored in the current channel n buffer at thecurrent index value of the array. If the analog to digital channel isnot greater than 7, the program stores the information received from theanalog to digital converter in the channel n buffer at the current indexvalue of the array. In the next stage, 514, if the analog to digitalchannel is not equal to 7, the program increments the channel andprogresses to stage 520. If the analog to digital channel is equal to 7,the channel is set to 0, the index is incremented and the program movesto stage 516. In stage 516, if the index is greater than the filter, theprogram sets the index equal to 0 and sets the newInputData flag,thereby acknowledging that the input data update is ready, andprogresses to stage 518. If the index is not greater than the filter,the program sets the newInputData flag, thereby acknowledging that theinput data update is ready, and progresses to stage 518.

In stage 518, the program examines the calMode flag. If the calMode flagis not set, the adTimer is restarted at 0 and the program progresses tostage 520. However, if the calMode flag is set, the newCalBuffer flag isset, the adTimer is restarted at 0, and the program progresses to stage520. Once in stage 520, if the newInputData flag is cleared, an inputdata update from the analog to digital converter 325 is not available,and the program progresses to stage 530. If the newInputData flag isset, an input data update is available, the input data is averaged, andthe temperature correction is calculated based on the temperature sensor340 input. The temperature correction formula in the preferredembodiment is as follows: (4.106e-07*(temperature sensor inputvalue)²)+(−4.952e-04*temperature sensor input value)+0.9830. Aftercalculating the temperature correction, the program advances to stage522.

In stage 522, if the calMode flag is set, the forward power output countis set equal to the forward power input count and scaled for output tothe digital to analog converter 345. The forward power input count isequal to the average input value from the forward gain stage 320. In thepreferred embodiment, the forward power output count sent to the digitalto analog converter 345 is equal to (forward power inputcount)*(ADSCALE), with ADSCALE=4.

If the calMode flag is not set, the forward power input count istemperature corrected by multiplying the forward power input count bythe temperature correction formula. The forward power input count isequal to the averaged input values from the forward gain stage 320. Theforward power input count is then “zero corrected” by subtracting theforward zero power offset count from the forward power input countbefore progressing to stage 524.

In stage 524, if the average input from the forward calibrationadjustment 330 is less than the predefined minimum threshold, theminimum forward gain ratio correction is applied to the forward powerinput count and the forward power input count is scaled for output tothe digital to analog converter 345. In the preferred embodiment, thepredetermined minimum threshold is 2080 and the forward power outputcount sent to the digital to analog converter 345 is equal to (forwardpower input count)*(POTMINSCALE)*(ADSCALE), with POTMINSCALE=1.0 andADSCALE=4. The ADSCALE value is used to scale the forward power inputcount for output to the digital to analog converter 345. Gain ratiocorrection is provided through the POTMINSCALE value.

However, if the average input from the forward calibration adjustment330 exceeds the predefined maximum threshold, the maximum forward gainratio correction is applied the forward power input count and theforward power output count is scaled for output to the digital to analogconverter 345. In the preferred embodiment, the predetermined maximumthreshold is 3680 and the forward power count outputted to the digitalto analog converter 345 is equal to (forward power inputcount)*(POTMAXSCALE)*(ADSCALE), with POTMAXSCALE=2.0 and ADSCALE=4. TheADSCALE value is used to scale the forward power input count for outputto the digital to analog converter. Gain ratio correction is providedthrough the POTMAXSCALE value.

However, if the average input from the forward calibration adjustment330 is between the minimum and maximum thresholds, the average inputfrom the forward calibration adjustment 330 is used to apply the gainratio correction to the forward power input count. The forward powerinput count is also scaled for output to the digital to analog converter345. In the preferred embodiment, the forward power count outputted tothe digital to analog converter 345 is equal to ((forward power inputcount)*((average input from the forward calibrationadjustment)/(POTSCALE))−(POTCONSTANT))*(ADSCALE), with POTSCALE=1600,POTCONSTANT=0.3, and ADSCALE=4. The ADSCALE value is used to scale theforward power input count for output to the digital to analog converter.Gain ratio correction is provided through ((average input from theforward calibration adjustment)/(POTSCALE))−(POTCONSTANT).

After applying the gain correction ratio to the forward power inputcount and scaling the forward power input count for to the digital toanalog converter, the program moves to stage 526.

In stage 526, if the calMode flag is set, the reflected power outputcount is set equal to the reflected power input count and scaled foroutput to the digital to analog converter 345. The reflected power inputcount is equal to the average input value from the reflected gain stage321. In the preferred embodiment, the reflected power output count sentto the digital to analog converter 345 is equal to (reflected powerinput count)*(ADSCALE), with ADSCALE=4.

If the calMode flag is not set, the reflected power input count istemperature corrected by multiplying the reflected power input count bythe temperature correction formula. The reflected power input count isequal to the averaged input values from the reflected gain stage 321.The reflected power input count is then “zero corrected” by subtractingthe reflected zero power offset count from the reflected power inputcount before progressing to stage 528.

In stage 528, if the average input from the reflected calibrationadjustment 331 is less than the predefined minimum threshold, theminimum reflected gain ratio correction is applied to the reflectedpower input count and the reflected power input count is scaled foroutput to the digital to analog converter 345. In the preferredembodiment, the predetermined minimum threshold is 2080 and thereflected power output count sent to the digital to analog converter 345is equal to (reflected power input count)*(POTMINSCALE)*(ADSCALE), withPOTMINSCALE=1.0 and ADSCALE=4. The ADSCALE value is used to scale thereflected power input count for output to the digital to analogconverter. Gain ratio correction is provided through the POTMINSCALEvalue.

However, if the average input from the reflected calibration adjustment331 exceeds the predefined maximum threshold, the maximum reflected gainratio correction is applied to the reflected power input count and thereflected power input count is scaled for output to the digital toanalog converter 345. In the preferred embodiment, the predeterminedmaximum threshold is 3680 and the reflected power count outputted to thedigital to analog converter 345 is equal to (reflected power inputcount)*(POTMAXSCALE)*(ADSCALE), with POTMAXSCALE=2.0 and ADSCALE=4. TheADSCALE value is used to scale the reflected power input count foroutput to the digital to analog converter. Gain ratio correction isprovided through the POTMAXSCALE value.

However, if the average input from the reflected calibration adjustment331 is between the minimum and maximum thresholds, the average inputfrom the reflected calibration adjustment 331 is used to scale thereflected power input count for output to the digital to analogconverter 345. In the preferred embodiment, the reflected power countoutputted to the digital to analog converter 345 is equal to ((reflectedpower input count)*((average input from the reflected calibrationadjustment)/(POTSCALE))−(POTCONSTANT))*(ADSCALE), with POTSCALE=1600,POTCONSTANT=0.3, and ADSCALE=4. The ADSCALE value is used to scale thereflected power input count for output to the digital to analogconverter. Gain ratio correction is provided through ((average inputfrom the reflected calibration adjustment)/(POTSCALE))−(POTCONSTANT).

After scaling the reflected power count for output, the newInputdataflag is cleared and the program moves to stage 530.

In stage 530, the forward and reflected power output counts are sent tothe digital to analog converter 345. If a forward or reflected poweroutput count is negative, the negative count is replaced with a 0 beforethe count is outputted to the digital to analog converter 345. If aforward or reflected power output count is greater than a thresholdlevel, the count exceeding the threshold level is replaced with adefault count before the count is outputted to the digital to analogconverter 345. In the preferred embodiment, any count that exceeds 16383is replaced with a default count of 16383. The analog forward andreflected power output counts are then sent from the digital to analogconverter 345 to the forward buffer 350 and reflected buffer 351.

Following stage 530, the program investigates whether the calibrationbutton 336 is depressed in stage 532. If the calibration button 336 isnot depressed and the calMode flag is cleared, the program restarts thecalButtonTimer at 0, clears the newCalBuffer flag, and moves to stage506. However, if the calibration button 336 is depressed or the calModeflag is set, the program moves to stage 534.

In stage 534, the program examines the calibration button 336, timer,and calMode flag status. If the calibration button 336 is depressed, thetimer is greater than 10, and the calMode flag is cleared, the programsets the calMode flag and clears the both calDone and newCalBuffer flagsbefore moving to stage 506. If the calibration button 336 is released,the timer is less than 10, or the calMode flag is set, the program movesto stage 536. In the preferred embodiment, the microcontroller 335senses the calibration button as depressed whenever pin 33 ofmicrocontroller 335 is pulled low. Pin 33 of microcontroller 335 isconnected to pin 9 of the male DE9 9-pin D-sub socket.

In stage 536, if the calibration button 336 is depressed, the calModeflag is cleared, or the calDone flag is set, the program progresses tostage 506. However, if the calibration button 336 is released, thecalMode flag is set, and the calDone flag is cleared, the programprogresses to stage 538. Once at stage 538, if the newCalBuffer flag isnot set, the program progresses to stage 506. However, if thenewCalBuffer flag is set, the forward and reflected zero power offsetcount memory is cleared, the temperature correction factor iscalculated, and the program progresses to stage 540.

In stage 540, if the forward zero power offset count is within apredetermined threshold, the temperature correction factor is applied tothe forward zero power offset count, the temperature corrected forwardzero power offset count is stored in the memory, and the programprogresses to stage 542. The forward zero power offset count is theaverage input value received from forward gain stage 320.

However, if the forward zero power offset count is not within apredetermined threshold, the default forward zero power offset count isstored in the memory and the program progresses to stage 542. In thepreferred embodiment, the forward zero power offset count is within thepredetermined limits if it is greater than 0 and less than or equal toMAXZEROOUT, with MAXZEROOUT=200. Further, in the preferred embodiment,the default forward zero power offset count is 0.

In stage 542, if the reflected zero power offset count is within apredetermined threshold, the temperature correction factor is applied tothe reflected zero power offset count, the temperature correctedreflected zero power offset count is stored in the memory, and theprogram progresses to stage 544. The reflected zero power offset countis the average input value received from reflected gain stage 321.

However, if the reflected zero power offset count is not within apredetermined threshold, the default reflected zero power offset countis stored in the memory and the program progresses to stage 544. In thepreferred embodiment, the reflected zero power offset count is withinthe predetermined limits if it is greater than 0 and less than or equalto MAXZEROOUT, with MAXZEROOUT=200. Further, in the preferredembodiment, the default reflected zero power offset count is 0.

In stage 544, the calibration temperature is stored in the memory, thecalDone flag is set, and the calMode flag is cleared before progressingto stage 506.

The default values, threshold or limit values, formulas, and programstructure discussed above in conjunction with the flow chart of FIG. 5are representative of those found in the preferred embodiment. However,it is contemplated that a person having ordinary skill in the art mayuse any values, formulas, or program structure that he sees fit.

Turning to FIG. 6A-H, FIG. 6A-B are an electrical schematic of the RFboard of an embodiment of the transmitter power monitor. FIG. 6C-F areelectrical schematics of the logic board of an embodiment of thetransmitter power monitor. FIG. 6G is an electrical schematic of thepower board of an embodiment of the transmitter power monitor. FIG. 6His an electrical schematic of the power board of a second embodiment ofthe transmitter power monitor.

While this invention has been described with respect to particularembodiments thereof, it is apparent that numerous other forms andmodifications of this invention will be obvious to those skilled in theart. The appended claims and this invention generally should beconstrued to cover all such obvious forms and modifications which arewithin the true spirit and scope of the present invention.

Benefits, other advantages, and solutions to problems have beendescribed above with regard to specific embodiments. However, thebenefits, advantages, solutions to problems, and any element(s) that maycause any benefit, advantage, or solution to occur or become morepronounced are not to be construed as critical, required, or essentialfeatures or elements of any or all the claims. As used herein, the terms“comprises, “comprising,” or any other variation thereof, are intendedto cover a non-exclusive inclusion, such that a process, method,article, or apparatus that comprises a list of elements does not includeonly those elements, but may include other elements not expressly listedor inherent to such process, method, article, or apparatus. Further, noelement described herein is required for the practice of the inventionunless expressly described as “essential” or “critical.”

What is claimed is:
 1. A power monitor comprising: a coupler configuredto sample radio frequency (“RF”) power propagating in one direction on atransmission line between a RF transmitter and an antenna, said RF powerhaving a level, said coupler is configured to generate a RF voltageproportional to said RF power level; a power splitter configured toreceive said RF voltage and output said RF voltage to a test port and adetector; said test port having a known mathematical relationship withsaid transmission line; said test port is configured to connect to areference power meter; said detector is configured to convert said RFvoltage to an analog DC voltage; a calibration adjustment configured tooutput a signal; an analog to digital converter configured to receiveand convert said analog DC voltage and said calibration adjustmentsignal into a digitized DC voltage and a digitized calibrationadjustment signal, said analog to digital converter sends said digitizedDC voltage and said digitized calibration adjustment signal to acorrection circuit; said correction circuit is configured to apply again ratio correction to said digitized DC voltage, thereby producing acorrected digitized DC voltage, said correction circuit is furtherconfigured to output said corrected digitized DC voltage to a digital toanalog converter, said gain ratio correction is dictated by saiddigitized calibration adjustment signal; said digital to analogconverter is configured to convert said corrected digitized DC voltageinto a corrected DC voltage; a power calibrated output configured tooutput said corrected DC voltage; wherein said a power calibrated outputis configured to output said corrected DC voltage to a power displayhaving a reading; wherein said calibration adjustment is adjusted by:connecting a reference power meter to said test port; using saidreference power meter to obtain a RF power level measurement readingfrom said transmission line while said RF transmitter is broadcastinglive; comparing said RF power level measurement reading with said powerdisplay reading, wherein said power display is configured to display afull scale power reading; when said power display reading is not within+/−1% of said RF power level measurement reading, adjusting the outputof said calibration adjustment such that said power display reading iswithin +/−1% of said RF power level measurement reading.
 2. The powermonitor of claim 1, wherein the step of connecting a reference powermeter to said test port includes inputting said known mathematicalrelationship between said transmission line and said test port into saidreference power meter.
 3. The power monitor of claim 1, furtherincluding a buffer between said digital to analog converter and saidpower calibrated output; an amplifier configured to amplify said analogDC voltage for processing by said analog to digital converter.
 4. Thepower monitor of claim 1, wherein said correction circuit comprises anintegrated circuit.
 5. The power monitor of claim 1, wherein saiddigital to analog converter and analog to digital converter areincorporated in said correction circuit.
 6. The power monitor of claim1, further comprising a temperature sensor having an output, wherebysaid correction circuit uses the output of said temperature sensor toapply a temperature correction to said digitized DC voltage; means forcalculating zero power offsets introduced by the circuitry of said powermonitor and applying a zero power offset correction to said digitized DCvoltage.
 7. The power monitor of claim 1, wherein said RF powerpropagating in one direction on said transmission line is forward RFpower.
 8. The power monitor of claim 1, wherein said RF powerpropagating in one direction on said transmission line is reflected RFpower.
 9. A power monitor comprising: a coupler configured to sampleradio frequency (“RF”) power propagating in one direction on atransmission line between a RF transmitter and an antenna, said RF powerhaving a level, said coupler is configured to generate a RF voltageproportional to said RF power level; a power splitter configured toreceive said RF voltage and output said RF voltage to a test port and adetector; said test port having a known mathematical relationship withsaid transmission line; said test port is configured to connect to areference power meter; said detector is configured to convert said RFvoltage to a DC voltage; a calibration adjustment configured to output asignal; a correction circuit configured to apply a gain ratio correctionto said DC voltage, thereby producing a corrected DC voltage, said gainratio correction is dictated by said calibration adjustment signal; apower calibrated output configured to output said corrected DC voltage;wherein said a power calibrated output is configured to output saidcorrected DC voltage to a power display having a reading; wherein saidcalibration adjustment is adjusted by: connecting a reference powermeter to said test port; using said reference power meter to obtain a RFpower level measurement reading from said transmission line while saidRF transmitter is broadcasting live; comparing said RF power levelmeasurement reading with said power display reading, wherein said powerdisplay is configured to display a full scale power reading; when saidpower display reading is not within +/−1% of said RF power levelmeasurement reading, adjusting the output of said calibration adjustmentsuch that said power display reading is within +/−1% of said RF powerlevel measurement reading.
 10. The power monitor of claim 9, wherein thestep of connecting a reference power meter to said test port includesinputting said known mathematical relationship between said transmissionline and said test port into said reference power meter.
 11. The powermonitor of claim 9, wherein said correction circuit comprises anintegrated circuit.
 12. The power monitor of claim 9, further comprisinga temperature sensor having an output, whereby said correction circuituses the output of said temperature sensor to apply a temperaturecorrection to said digitized DC voltage; means for calculating zeropower offsets introduced by the circuitry of said power monitor andapplying a zero power offset correction to said digitized DC voltage.13. The power monitor of claim 9, wherein said RF power propagating inone direction on said transmission line is forward RF power.
 14. Thepower monitor of claim 9, wherein said RF power propagating in onedirection on said transmission line is reflected RF power.